FR2783968A1 - Deflection yoke for cathode ray tube (CRT), comprises coil separator with horizontal and vertical deflection coils - Google Patents

Abstract

The yoke comprises a coil separator (11) with a rear plate (11a) and a neck part to which a printed circuit board is attached. A horizontal deflection coils is disposed inside the coil separator and connected to the circuit board, and a vertical deflection coil (13) is disposed outside the separator as is a ferrite core (14). The coil separator is provided with an insulating device (100) which prevents shorting of the ends of the horizontal deflection coil where they are connected to the circuit board. The insulating device may be provided at the boundary between the two halves of the separator. The coil separator may also have another part (200) which ensures a safe separation of the horizontal and vertical deflection coils. The ferrite core may have grooves (14a, b) in which elastic projections (400, 500) on the coil separator engage in order to locate the ferrite core accurately relative to the coil separator and thus correct for misconvergence and geometrical distortion.

Description

The invention relates to a deflection block or collar and more

  particularly the invention relates to a deflection block which improves the dispersion of the image due to an assembly distortion of a vertical deflection coil and improves the winding structures of the vertical deflection coil and of a reel of horizontal deviation. Generally a deflection block used in a cathode ray tube in a television receiver or a monitor is subdivided into a deflection block of the saddle-torus type and a deflection coil of the saddle-saddle type and acts so to precisely deflect the electron beams emitted by electron guns towards a fluorescent layer applied to a screen of a tube

cathodic.

  In other words, as shown in FIG. 1 appended to the present application, the conventional deflection block 10 is mounted around a part

  forming the neck of a cathode ray tube 1. As has been described

  previously, the deflection block 10 is subdivided into a deflection block of the saddle-saddle type as shown in FIGS. 2 and 3, appended to the request request and a deflection coil of the selletore type as shown on

  Figures 4 and 5, appended to this application, er.

  function of the winding structure of a coil of this block. The deflection block 10 is used to deflect horizontally and vertically the electron beam emitted by the blue, green and red electron cannons 3, which are arranged in the neck portion 2 of the cathode ray tube 1, so as to focus precisely the electron beams on a fluorescent layer of the cathode ray tube 1. Figures 2 and 3 show the deflection block of the conventional saddle-saddle tvpe. As can be seen in Figures 2 and 3, in the saddle-saddle type deflection block, horizontal deflection coils 2 have a saddle-like configuration are arranged on upper and lower parts of a circumferential inner surface a screen portion of a coil separator 11 having a substantially frustoconical configuration, and vertical deflection coils 13 having a saddle-like configuration are disposed on the left and right portions of a circumferential outer surface of the portion

  forming the screen of the coil separator 11.

  A ferrite core 14 having a substantially cylindrical configuration is disposed on the circumferential outer surface of the screen portion of the coil separator 11 to strengthen a magnetic field

  vertical deflection coils 13.

  Likewise coils 15 having no coma are disposed in the vicinity of the circumference of the outlet forming the neck of the coil separator 11 so as to compensate for the coma produced by the deflection coils

vertical 13.

  Figures 4 and 5 show the deflection block of the conventional saddle-torus type. As can be seen in Figures 4 and 5, in the saddle-torus type deflection block, horizontal deflection coils 12 are arranged on the upper and lower parts of a circumferential inner surface of a screen portion d a coil separator 11 having a substantially frustoconical configuration, a ferrite core 14 having a substantially cylindrical configuration is disposed on an outer circumferential surface of the screen portion of the coil separator 11, and vertical deflection coils having a configuration torus shape are arranged on the upper parts

  and lower of the ferrite core 14.

  In addition, coma-free coils 15 are additionally arranged in the vicinity of the circumference of the neck portion of the coil separator l to compensate for the coma which is produced by the coils.

vertical deflection 16.

  In addition, in the saddle-type deflection block and in the saddle-toroid type deflection block, a printed circuit board is arranged on one side of the coil separator 11il so as to send energy to the deflection coils horizontal 12 and to the coils of

vertical deviation 13 and 16.

  However, the classic deflection coils

  have defects as will be described later.

  In other words, during the delivery process

  ment of the ferrite core 14, around which the vertical deflection coils 13 are wound, on the circumferential outer surface of the coil separator 11, on the circumferential lower surface of which the horizontal deflection coils 12 are mounted, by means of the use of a core clamping member (not shown), the ferrite core 13 may be subject to fluctuations due to the dispersion of its dimensions, the dispersion of the winding of the vertical deflection coil 13, etc. That is to say that the ferrite core 14 can be made to fluctuate on the coil separator 1i in a transverse or longitudinal direction even under

the effect of a weak shock.

  As described above, if the ferrite core 14, around which the vertical deflection coils 13 are wound, is the seat of fluctuation on the coil separator 11, since the vertical deflection coils 13 cannot not be precisely aligned concentrically with the coil separator 11, a stable axial balance cannot be

  guaranteed, resulting in image distortion.

  Indeed, in the saddle type deviation block-

  saddle, there is a difference between the left magnetic field and the right magnetic field due to a relative dispersion and / or a relative amount of current between the vertical deflection coils on the left and the vertical deflection coils on right, which results in a defect in the image

  convergence and geometric distortion (L / R).

  Similarly, also in the case of the saddle-torus type deflection block, a difference appears between the left magnetic field and the right magnetic field, due to a relative dispersion and / or an amount of relative current between the vertical deflection coils 16 arranged on the upper and lower left parts of the ferrite core 14 and the vertical deflection coils 16 disposed on the upper and lower right parts of the ferrite core 14, on XY axes, which leads to the appearance, in the image, of a defect of convergence and a geometric distortion

(L / R).

  The convergence defect is distributed between a

  YV convergence fault and YHC convergence fault.

  The defect of convergence YV represents a defect of vertical convergence, according to which a transverse line of red color R is not aligned with the transverse lines of blue color B on the upper and lower parts of the Y axis as shown in the figures 6 and 7 appended to the present application, and the defect of convergence YHC represents a defect of horizontal convergence, in which a longitudinal line of red color R crosses a longitudinal line of blue color B as represented in FIG. 8, appended to the present request. The geometric distortion (L / R) represents a state in which an image is not normal, but is distorted as shown in Figures 9 and 10 annexed to this application, which illustrate specifically

  a trapezoidal distortion of the image.

  To solve the problems appearing in the associated technique, as shown in FIG. 11, appended to the present application, a plurality of elastic corners, which are formed of a sponge, are fixed on the outer circumferential surface of the coil separator 11 such that they are uniformly spaced from each other in a circumferential direction, so as to elastically bias the ferrite core 14 which is placed on the circumferential outer surface of the coil separator 11, which has the effect of reducing assembly dispersion by eliminating the cited defects

with reference to Figures 2 to 10.

  However in the method of maintaining an axial balance between the vertical deflection coils 13 through the use of the plurality of elastic corners, since the elastic corners are themselves deformed to a significant degree, one cannot obtain a high dimensional accuracy and, therefore, dimensional dispersion is increased, making it difficult to effectively achieve balance

  axial of the vertical deflection coils.

  Furthermore, since the plurality of elastic corners are fixed to the circumferential outer surface of the coil separator 11 by application of an adhesive, the fixing position varies depending on the operator, which results in the dispersion of the fixing position is increased, and therefore it is more difficult to obtain, in a stable manner,

  the axial balance of the vertical deflection coils 13.

  Furthermore, since a plurality of elastic corners are used, the number of components and the cost are increased, and since the number of operating steps including the step of applying the adhesive to fix the plurality of elastic corners increases, the capacity of

  reduced labor and productivity.

  In addition, although one end and the other end of the horizontal deflection coil 12 must be connected to the printed circuit board when it is disposed on the circumferential inner surface of the coil separator 11, since the positions of gripping are close to each other, the end and the other end of the horizontal deflection coil 12

  can be brought into reciprocal contact due to the negligence of an operator, which shows a short-

  circuit or an electric shock and when connecting the vertical deflection coils 13 and 16 to the printed circuit board, a short circuit or an electric shock15 may be produced due to contact between the horizontal deflection coil 12 and the coils vertical deflection 13 and 16. This is why the present invention has been developed with a view to solving the problems appearing in the associated art, and an object of the present invention is to provide a deflection block, which makes it possible to prevent the fluctuation of a ferrite core, in order to improve the dispersion of the image, and makes it possible to prevent the appearance of a short circuit and an electric shock during

  winding of horizontal and vertical deflection coils.

  According to one aspect of the present invention, there is provided a deflection block characterized in that it comprises: a coil separator comprising a rear plate and a neck portion, which are arranged in the coil separator and a panel printed circuits, which is arranged on one side of the coil separator; at least one horizontal deflection coil disposed on a circumferential surface of the -7 coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board; at least one vertical deflection coil disposed on a circumferential outer surface of the coil separator to produce a vertical magnetic field; a ferrite core placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils, and insulating means formed on a lower surface of the coil separator to prevent the occurrence of a short circuit due to contact between one end and the other end of the horizontal deflection coil connected to the panel

printed circuits.

  According to another aspect of the present invention, the insulating means are arranged between boundary surfaces of halves of the coil separator, which are joined to one another. According to another aspect of the present invention, the insulating means comprise a separating element which is formed on a boundary surface of one half of the coil separator so that it extends in the direction of the other boundary surface of the other half of the coil separator to make a separation above and below

  the other end of the horizontal deflection coil.

  According to another aspect of the present invention, a deflection block is provided, characterized in that it comprises: a coil separator comprising a rear plate and a neck portion, which are arranged in the coil separator and a panel printed circuits, which is arranged on one side of this coil separator; at least one horizontal deflection coil disposed on a circumferential surface of the coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board; at least one vertical deflection coil disposed on a circumferential outer surface of the coil separator to produce a vertical magnetic field; a ferrite core placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils, and means for maintaining the distance between coils, which are formed on an outer surface of one side of the coil holder to ensure a safe distance between the deflection coils

horizontal and vertical.

  According to another aspect of the present invention, the means for maintaining the distance between coils comprises an insulating element which is formed on a surface situated on one side of the plate of the coil separator so that it extends, while maintaining a predetermined distance from an outer surface of the back plate, so as to isolate them from each other

  horizontal and vertical deflection coils.

  According to another aspect of the present invention, a deflection block is provided, characterized in that it comprises: a coil separator comprising a rear plate and a neck portion, which are arranged in the coil separator and a panel printed circuits, which is arranged on one side of this coil separator; at least one horizontal deflection coil disposed on a circumferential surface of the coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board; at least one vertical deflection coil disposed on a circumferential outer surface of the coil separator to produce a vertical magnetic field; a ferrite core placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils; insulating means formed on a lower surface of the coil separator to prevent the occurrence of a short circuit due to contact between one end and the other end of the horizontal deflection coil connected to the printed circuit board; and means for maintaining the distance between coils, which are formed on an outer surface on one side of the coil support to guarantee a safe distance between the horizontal deflection coils and

vertical.

  According to another aspect of the present invention, characterized in that it comprises: a coil separator having a back plate and a neck portion, which are arranged in the coil separator and a printed circuit board, which is arranged one side of the coil separator; at least one horizontal deflection coil disposed on a circumferential surface of the coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board; at least one vertical deflection coil disposed on a circumferential outer surface of the coil separator to produce a vertical magnetic field; a ferrite core placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils, and having: at least a pair of grooves having a predetermined width, which are formed on the surfaces upper and lower central spools; means for preventing fluctuation, which are formed on the coil separator so that these means have a predetermined elasticity so as to resiliently support the internal surfaces of the pair of grooves in the ferrite core so as to prevent the latter from fluctuates when coupled to the coil separator. According to another aspect of the present invention, the means for preventing fluctuation comprise at least two pairs of elastic protrusions, which are formed so that these two couples extend: respectively from an upper inner surface and of a lower inner surface of the coil separator and correspond respectively to the pair of grooves formed in the ferrite core, the two elastic projecting parts of each pair extending parallel to each other, and the two pairs of elastic projecting parts being elastically inserted respectively in the pair of grooves in the ferrite core in order to compensate for a range of width tolerances of 0.1 mm - 1.0 mm that each groove in the ferrite core has. According to another aspect of the present invention, i

  a diversion block is provided, characterized in that i.

  comprises: a coil separator having a back plate and a neck portion, which are arranged in the coil separator and a printed circuit board, which is arranged on one side of this coil separator; at least one horizontal deflection coil disposed on a circumferential surface of the coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board; at least one vertical deflection coil disposed on a circumferential outer surface of the coil separator to produce a vertical magnetic field; a ferrite core placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils, and having at least a pair of grooves having a predetermined width, which

  are formed on the upper central surfaces e.

  lower coils; means for preventing fluctuation, which are formed on the coil separator so that these means have a predetermined elasticity so as to resiliently support the internal surfaces of the pair of grooves in the ferrite core so as to prevent the latter from fluctuates when coupled to the coil separator; insulating means formed on a lower surface of the coil separator to prevent the occurrence of a short circuit due to contact between one end and the other end of the horizontal deflection coil connected to the printed circuit board; means for maintaining the distance between coils, which are formed on an outer surface on one side of the coil support to guarantee a safe distance between the horizontal and vertical deflection coils; and means for preventing fluctuation, which are formed on the coil separator such that these means have a predetermined elasticity so as to resiliently support the interior surfaces of the pair of grooves of the ferrite core so as to prevent the latter does not fluctuate

  if it is coupled to the coil separator.

  Other features and advantages of the

  present invention will emerge from the description given

  hereinafter taken with reference to the accompanying drawings, in which: FIG. 1, which has already been mentioned, is a side elevation view of the conventional deflection block;

  - Figures 2, 3, which has already been done

  mention, are respectively a longitudinal sectional view and a cross-sectional view illustrating the conventional deflection block of the saddle-saddle type; - Figures 4 and 5, given it has already been mentioned, respectively represent a longitudinal sectional view and a cross-sectional view illustrating the conventional deflection block of the saddle-torus type; - Figures 6 to 10, which have already been mentioned, are views for explaining a convergence defect diagram and a geometric distortion diagram in an image; - Figure 11 which has already been mentioned, is a front view illustrating the main components of the conventional deflection block; - Figures 12 and 15 are front views illustrating deflection blocks according to several embodiments of the present invention; - Figures 13 and 14 are respectively a partial perspective view and a cross-sectional view of the deflection block of Figure 12; and Figure 16 is a front view of main components of the deflection block of Figure 15, illustrating

  a ferrite core in the coupled state.

  We will now refer in more detail to an embodiment of the invention, an example of which is shown in the accompanying drawings. Whenever possible, the same digits of

  reference in the set of drawings and description

  to designate the same elements or elements

similar.

  We will describe a deflection block according to a first embodiment of the present invention with reference to Figures 2 to 5, then with reference to the figures

12 and 13.

  Figures 2 and 3 show the conventional deflection block of the saddle-saddle type. As can be seen in FIGS. 2 and 3, in the saddle-saddle type deflection block, horizontal deflection coils having the saddle-shaped configurations are arranged on the upper and lower parts of the circumferential inner surface of a screen portion of a coil separator 11 having a substantially frustoconical configuration, and vertical deflection coils 13 having a saddle-shaped configuration are disposed on the left and right portions of a circumferential outer surface of the portion

  forming the screen of the coil separator 11.

  A ferrite core 14 having a substantially cylindrical configuration is placed on the circumferential outer surface of the screen portion of the coil separator 11 to strengthen a magnetic field

  vertical deflection coils 13.

  Likewise, coma-free coils 15 are disposed in the vicinity of the circumference of the neck portion of the coil separator 11, i.e. on a back plate 11a, so as to compensate for the coma which

  is produced by the vertical deflection coils 13.

  Figures 4 and 5 show the conventional deflection coil of the saddle-core type. As can be seen in FIGS. 4 and 5, in the saddle-torus type deflection coil, horizontal deflection coils 12 are arranged on the upper and lower parts of a circumferential inner surface of a screen portion d 'a coil separator 11 having a substantially frustoconical configuration. A ferrite core 14 having a substantially cylindrical configuration is placed on a circumferential outer surface on the screen portion of the coil separator 11, and vertical deflection coils 16 having a toroidal configuration are disposed on the portions

  upper and lower of the ferrite core 14.

  In addition coils free from coma 15 sound. additionally arranged in the vicinity of the circumference of the neck portion of the coil separator 11 so as to compensate for the coma which is produced by the

vertical deflection coils 16.

  In addition, in the saddle-type deflection block-

  saddle and in the saddle-toroid type deflection block, a printed circuit board 17 is positioned on one side of the coil separator 11 so as to send power supply to the horizontal deflection coils 12 and to the vertical deflection coils 13 and 16. With reference to FIG. 12, insulating means are defined on an inner surface of the coil separator 11 so as to prevent one end from the other end of the horizontal deflection coil 12 connected to the panel printed circuits 17 are placed in reciprocal contact, that is to say to prevent

the appearance of a short circuit.

  The insulating means are provided between the boundary surfaces of the halves of the coil separator, which are joined together to complete the coil separator 11. As insulating means, as shown in FIG. 13, a separating element 100 is formed on a boundary surface of one half of the coil separator so as to extend towards the other boundary surface

  on the other half of the coil separator.

  Therefore, since one end e: the other end of the horizontal deflection coil 12 are connected to the printed circuit board 17 in a state in which they are separated by being arranged one above and the other below the separating element 100 while being centered relative to the latter, it is possible to prevent a short circuit and an electric shock under the effect of contact between the end and the other end of the horizontal deflection coil 12, which otherwise may occur during a process of

connection of the coils.

  We are going to write a deflection block according to a second embodiment of the present invention by first referring to the first embodiment of the present invention, then by referring

in Figures 12 to 14.

  Figures 2 and 3 show the conventional deflection block of the saddle-saddle type. As can be seen in FIGS. 2 and 3, in the saddle-saddle type deflection block, horizontal deflection coils 12 having a saddle-like configuration are arranged on the upper and lower parts of the circumferential inner surface d a screen part of a coil separator 11 having a substantially frustoconical configuration, and vertical deflection coils 13 having a saddle-shaped configuration are arranged on the left and right parts of a circumferential outer surface of the part

  forming the screen of the coil separator 11.

  A ferrite core 14 having a substantially cylindrical configuration is provided on the circumferential outer surface of the screen portion of the coil separator 11 to strengthen the magnetic field

  vertical deflection coils 13.

  Likewise, coma-free coils 15 are disposed in the vicinity of the circumference of the neck portion of the coil separator 11, that is to say on

  a back plate lia to compensate for the coma that is

  produced by the vertical deflection coils 13.

  Figures 4 and 5 show the conventional deflection block of the saddle-torus type. As can be seen in Figures 4 and 5, in the saddle-torus type deflection block, horizontal deflection coils 12 are arranged on upper and lower parts - of an inner circumferential surface of a screen part of a coil separator 11 having a substantially frustoconical configuration, a ferrite core 14 having a substantially cylindrical configuration and placed on an outer circumferential surface of the screen portion of the coil separator 11, and the vertical deflection coils 16 having a toroidal configuration are arranged on the

  upper and lower parts of the ferrite core 14.

  In addition coils free from coma 15 sound.

  additionally arranged in the vicinity of the circumference of the neck-shaped part of the coil separator 11 to compensate for the coma which is produced by the coils of

vertical deflection 16.

  Also in the saddle-type deflection block

  saddle and in the saddle-toroid type deflection block, a printed circuit board 17 as shown in FIG. 12 is positioned on one side of the coil separator 11 so as to send power to the horizontal deflection coils 12 and to the deflection coils

vertical 13 and 16.

  Means for maintaining the distance between coils are formed on an external surface of the coil separator 11 so as to fix a safe distance between the horizontal and vertical deflection coils 12 and 13, that is to say to prevent the horizontal and vertical deflection coils 12 e 13 are placed

reciprocally in contact.

  Indeed, as shown in Figures 13 and 14, an insulating element 200 extends from the outer surface of the coil separator 11, on a

predetermined distance.

  Then, the insulating element 200 is formed so that a predetermined distance is maintained between this element and an outer surface of the rear plate island.

of the coil separator 11.

  Therefore, by providing that the horizontal deflection coils 12 and the vertical deflection coils 13 are guided respectively on the outer surface of the back plate 11a and on the outer surface of the insulating element 200, a safe distance between the coils horizontal deflection 12 and the vertical deflection coils 13 can be fixed with a

enough.

  There will be described, with reference to the first and second embodiments of the present invention, a deflection coil in accordance with a third form of

  realization of the present invention.

  Figures 2 and 3 show the conventional deflection block of the saddle-saddle type. As can be seen in FIGS. 2 and 3, in the saddle-saddle type deflection block, horizontal deflection coils 12 having a sound saddle-like configuration: arranged on the upper and lower parts of an inner surface circumferential of a forman part: screen of a coil separator il having a substantially frustoconical configuration, and vertical deflection coils 13 having a saddle-shaped configuration are arranged on the left and right parts of a circumferential outer surface of the part

  forming the screen of the coil separator 11.

  A ferrite core 14 having a substantially cylindrical configuration is disposed on the circumferential outer surface of the screen portion of the coil separator 11 so as to strengthen the chamo

  magnetic of the vertical deflection coils 13.

  Likewise, coils free from coma 15 sound: arranged in the vicinity of the circumference of the neck portion of the coil separator 11, that is to say on a back plate 11a, so as to compensate for the coma which

  is produced by the vertical deflection coils 13.

  Figures 4 and 5 show the conventional deflection block of the saddle-torus type. As can be seen in Figures 4 and 5, in the saddle-torus type deflection block, horizontal deflection coils 12 are arranged on the upper and lower parts of a circumferential inner surface of a screen portion of the coil separator 11 having a substantially frustoconical configuration, and a ferrite core 14 having a substantially cylindrical configuration is placed on a circumferential outer surface of the screen portion of the coil separator 11, and vertical deflection coils 16 having a configuration toroidal shape are arranged on the upper and lower parts of the core

of ferrite 14.

  In addition, coma-free coils 15 are additionally arranged in the vicinity of the circumference of the neck portion of the coil separator 11, to compensate for the coma which is produced by the coils of

vertical deflection 16.

  In addition, in the saddle-type deflection block-

  saddle and in the saddle-torus type deflection block, a printed circuit board 17 as shown in FIG. 12 is arranged on one side of the coil separator 1i so as to send energy to the horizontal deflection coils 12 and to the vertical deflection coils 13 and 16. With reference to reference 12, insulating means are formed on an inner surface of the coil separator 11 so as to prevent the ends of the horizontal deflection coil 12 connected to the printed circuit board 17 are placed reciprocally in contact, that is to say to prevent the appearance of a short circuit. Means for maintaining the distance between coils are formed on an outer surface of the coil separator 11 to fix a safe distance between the coils

  horizontal and vertical deviation 12 and 13, that is

  say to prevent the horizontal and vertical deflection coils 12 and 13 from being placed in contact with each other. The previously mentioned insulating means are provided between the boundary surfaces of the halves of the coil separator, which are assembled one on the other to complete the coil separator 11. As insulating means, as shown in FIG. 13, an element of separation 100 is formed on a boundary surface of one half of the coil separator so that it extends towards the other boundary surface of the other half of the

coil separator.

  Therefore, since both ends of the horizontal deflection coil are connected to the printed circuit board 17 in a state in which

  they are separated by being located above and above

  below the separating element 10 while being centered

  around the latter it is possible to prevent a short

  circuit and an electric shock due to contact between the two ends, which can otherwise be produced in a

coil connection process.

  When studying a detailed construction of the means for maintaining the distance between coils serving to fix a safe distance between the horizontal and vertical deflection coils 12 and 13, as shown in FIGS. 13 and 14, an insulating element 200 extends at a predetermined distance from the outer surface of the

coil separator 11.

  Then, the insulating element 200 is formed so that the predetermined distance is maintained between itself and the outer surface of the rear plate 11a.

of the coil separator 11.

  Therefore, by providing for guiding the horizontal deflection coils 12 and the vertical deflection coils 13 respectively on the outer surface of the back plate 11a on an outer surface and on the insulating member 200, a safe distance can be sufficiently guaranteed between the horizontal deflection coils 12 and the vertical deflection coils 13. As described above, in accordance with the present invention, the operations of winding the horizontal and vertical deflection coils 12 and 13 and the operations of connection to the panel printed circuits 17 can be executed in a stable manner by means of the separating element 100 and the insulating element 200, which are formed on the coil separator 11, and specifically the appearance of a short circuit and a

  electric shock can be prevented.

  We will describe a deflection block according to a fourth embodiment of the present invention, first referring to the first three embodiments of the present invention, and then referring

in Figures 15 and 16.

  Figures 2 and - 3 show the conventional deflection block of the saddle-saddle type. As we can see: in Figures 2 and 3, in the saddle-saddle type deflection block, horizontal deflection coils having a saddle-like configuration are arranged on the upper and lower parts of the circumferential inner surface d a screen part of a coil separator 11 having a substantially frustoconical configuration, and vertical deflection coils 13 having a saddle-shaped configuration are arranged on the left and right parts of a circumferential outer surface of the part

  forming the screen of the coil separator 11.

  A ferrite core 14 having a substantially cylindrical configuration is placed on the circumferential outer surface of the screen portion of the coil separator 11 to strengthen a magnetic field

  vertical deflection coils 13.

  Likewise, coma-free coils 15 are disposed in the vicinity of the circumference of the neck portion of the coil separator 11, i.e. on a back plate 11a, so as to compensate for the coma which

  is produced by the vertical deflection coils 13.

  Figures 4 and 5 show the conventional deflection block of the saddle-torus type. As can be seen in FIGS. 4 and 5, in the saddle-toroid type deflection block, horizontal deflection coils 12 are arranged on the upper and lower parts of a circumferential inner surface of a screen portion. a coil separator 11 having a substantially frustoconical configuration. A ferrite core 14 having a substantially cylindrical configuration and placed on a circumferential outer surface on the screen portion of the coil separator 11, and vertical deflection coils 16 having a toroidal configuration are disposed on the portions

  upper and lower of the ferrite core 14.

  A pair of grooves 14a, 14b having a predetermined width and a predetermined depth have formed respectively on the upper central surfaces and

bottom of the ferrite core 14.

  In addition, coma-free coils 15 are additionally arranged in the vicinity of the circumference of the neck portion of the coil separator 11 so as to compensate for the coma which is produced by the

vertical deflection coils 16.

  In addition, in the saddle-type deflection block-

  saddle and in the saddle-torus type deflection block, a printed circuit board 17 is positioned on one side of the coil separator 11 so as to send energy to the horizontal deflection coils 12 and to:.:

  vertical deflection coils 13 and 16.

  On a top surface and on a surface

  lower side of the coil separator 11, i.e.

  say in a manner corresponding respectively to the pair of grooves 14a and 14b of the ferrite core 14, there are provided means serving to prevent fluctuation and which must be mounted in the pair of grooves 14a and 14b to prevent fluctuation of the ferrite core 14 when the

  ferrite core 14 is coupled to the coil separator 11.

  In particular, the means used to prevent a

  fluctuation are formed in such a way that they support-

  elastically of the inner surfaces of the pair of grooves 14a and 14b of the ferrite core 14, which eliminates the problem linked to a variation in the width of the pair of grooves 14a and 14b when the coupling of the ferrite core 14 to the coil separator 11 is produced, which may appear during the manufacture of the ferrite core 14. The means used to prevent fluctuation include two pairs of elastic protrusions of left and right 400 and 500, which are formed so that the two couples s 'extend respectively from an upper inner surface and a lower inner surface of the coil separator 11, the two couples corresponding respectively to the pair of grooves 14a and 14b, formed in the ferrite core 14 and, while the parts protruding elastic left and

  on the right 400 and 500 of each couple extends-

  parallel to each other, the two pairs of elastic protrusions on the left and on the right 400 and 500 being mounted elasuically respectively in the couple

  of grooves 14a and 14b, of the ferrite core 14.

  Then, the elastic protrusions on the left and on the right 400 and 500 are spaced from each other by a desired distance so as to compensate correctly. N: a dispersion, for example a dimensional tolerance which the ferrite core has 14, during mating

  from the latter to the coil separator 11.

  In other words, the elastic left and right projecting parts 400 and 500 are separated from each other by the desired distance, so as to compensate for a tolerance dispersion of the pair of grooves 14a and 14b, which appears during the formation of the nucleus of

ferrite 14.

  In general, the tolerance dispersion over the width of the pair of grooves 14a and 14b of the ferrite core 14 is equal to T 0.1 mm - 1.0 mm, T

representing the width.

  Therefore, to achieve the elastic support of the interior surfaces of the pair of grooves 14a and 14b of the ferrite core 14, the distance between the elastic projections on the left and on the right 400 and 500 does not

  must not be less than 1.0 mm.

  With this embodiment of the present invention, since the elastic protrusions of left and right 400 and 500 are mounted elastically in the pair of grooves 14a and 14b, when the ferrite core 14 is coupled to the coil separator 11 , this makes it possible to stably prevent rotation or

  a fluctuation in the ferrite core 14.

  Then, given that the elastic left and right projecting parts 400 and 500 are resiliently mounted on the pair of grooves 14a and 14b while they are separated by a desired distance which is not less than a dispersion range of tolerance on the width of the pair of grooves 14a and 14b of the ferrite core 14, all the ferrite cores 14 comprising pairs of grooves 14a and 14b, which have a tolerance range of 0.1 mm - 1.0 mm, can be stably coupled to the coil separator 11. Specifically, it is possible to prevent rotation and fluctuation of the ferrite core 14 after its coupling to the

coil separator 11.

  We will describe a deflection block according to a fifth embodiment of the invention with reference to the first four embodiments of the present invention. Figures 2 and 3 illustrate the conventional deflection block of the saddle-saddle type. As can be seen in Figures 2 and 3, in the saddle-saddle deflection block, horizontal deflection coils 12 having a saddle-like configuration are disposed on the upper and lower parts of a circumferential inner surface in a screen portion of the coil separator 11 having a substantially frusto-conical configuration, and vertical deflection coils 13 having a saddle-like configuration are disposed on the left and right portions of a circumferential outer surface of the form part

  screen of the wound separator 11.

  A ferrite core 14 having a substantially cylindrical configuration is disposed on the circumferential outer surface of the screen portion of the coil separator 11 so as to strengthen a field

  magnetic of the vertical deflection coils 13.

  Likewise, coils free from coma 15 sound: disposed in the vicinity of the circumference of the neck portion of the coil separator 11, that is to say according to a rear plate 11a so as to compensate for coma, which

  is produced by the vertical deflection coils 13.

  Figures 4 and 5 illustrate the conventional deflection block of the saddle-torus type. As we can see on the

  Figures 4 and 5, in the saddle-type deflection block

  toroid, horizontal deflection coils 12 are arranged on the upper and lower parts of a circumferential inner surface of a screen part of a coil separator 11 having a substantially frustoconical configuration, a ferrite core 14 having a substantially conformation cylindrical and disposed on an outer circumferential surface of the screen portion of the coil separator 11, and vertical deflection coils 16 having a toroidal configuration are disposed on the

  upper and lower parts of the ferrite core 14.

  A pair of grooves 14a and 14b having a predetermined width and a predetermined depth are formed respectively on upper central surfaces and

bottom of the ferrite core.

  In addition, coma-free coils 15 are additionally arranged in the vicinity of the circumference of the neck portion of the coil separator 11, so as to compensate for the coma, which is produced by the

deflection coils 16.

  In addition, in the saddle-type deflection block-

  saddle and in the saddle-torus type deflection block, a printed circuit board 17 as shown in FIG. 12 is positioned on one side of the coil separator 11 so as to supply power to the horizontal deflection coils 12 and deflection coils

vertical 13 and 16.

  Referring to Figure 12, insulating means are formed on an inner surface of the coil separator 11 so as to prevent the two ends of the horizontal deflection coil connected to the printed circuit board 17 from being placed in contact with each other, c that is, to prevent the occurrence of a short circuit. Means for maintaining the distance between coils are formed on an outer surface of the coil separator 11 to fix a safe distance between the coils

  horizontal and vertical deviation 12 and 13, that is

  say to prevent the horizontal and vertical deflection coils 12 and 13 from being placed in contact with each other. The above-mentioned insulating means are provided between the boundary surfaces of the halves of the coil separator, which are assembled so as to form the coil separator 11. As insulating means, as shown in FIG. 12, a separation element 100 is formed on a boundary surface of one half of the coil separator, so that it extends towards the other boundary surface of the other half of the coil separator. Therefore, since the two ends of the horizontal deflection coil 12 are connected to the printed circuit board 17 in a state in which they are separated above and below the separating element 100 while being centered around the latter, it is possible to prevent a short circuit and an electric shock due to contact between the two ends of the horizontal deflection coil 12 and which otherwise may:

  appear during a coil connection process.

  When considering a detailed construction of the means for maintaining the distance between coils serving to fix a safe distance between the horizontal and vertical deflection coils 12 and 13, as shown in FIGS. 13 and 14, an insulating element 200 extends at a predetermined distance from the outer surface

of the coil separator 11.

  Then, the insulating element 200 is formed so that the predetermined distance is maintained between this: element and an external surface of the rear plate Ile

of the coil separator 11.

  Consequently, on an upper surface and on a lower surface on one side of the coil separator 11, that is to say corresponding respectively to the pair of grooves 14a and 14b of the ferrite core 14, means are provided for preventing fluctuation and which must be mounted in the pair of grooves 14a and 14b to prevent fluctuation of the ferrite core 14 when this

  the latter is coupled to the coil separator 11.

  In particular, the means serving to prevent a fluctuation are formed so that they resiliently support internal surfaces of the pair of grooves 14a and 14b of the ferrite core 14, which eliminates the problem linked to a variation in the width of the pair grooves 14a and 14b when the coupling of the ferrite core 14 to the coil separator 11 is carried out, which may appear during the manufacture of the ferrite core 14. The means used to prevent fluctuation include two pairs of elastic projecting parts left and right 400 and 500, which are formed such that the two couples extend respectively from an upper inner surface and from a lower inner surface of the coil separator 11, the two couples respectively corresponding to the couple grooves 14a and 14b, formed in the ferrite core 14 and, while the elastic projections on the left e: on the right 400 and 500 of each pair extend parallel to each other, the two pairs of elastic protrusions on the left and on the right 400 and 500 being resiliently mounted in the pair respectively

  of grooves 14a and 14b of the ferrite core 14.

  Then, the elastic protrusions on the left and on the right 400 and 500 are spaced from each other by a desired distance so as to correctly compensate for a dispersion, for example a dimensional tolerance that the ferrite core 14 exhibits, during of the coupling

  from the latter to the coil separator 11.

  In other words, the elastic left and right projecting parts 400 and 500 are separated from each other by the desired distance, so as to compensate for a tolerance dispersion of the pair of grooves 14a and 14b, which appears during the formation of the nucleus of

ferrite 14.

  In general, the tolerance dispersion over the width of the pair of grooves 14a and 14b of the ferrite core 14 is equal to T 0.1 mm - 1.0 mm, T

representing the width.

  Therefore, to achieve the elastic support of the interior surfaces of the pair of grooves 14a and 14b of the ferrite core 14, the distance between the elastic projections on the left and on the right 400 and 500 does not

  must not be less than 1.0 mm.

  As described above, in accordance with the present invention, the operations of winding the horizontal and vertical deflection coils 12 and 13 and the operations of bonding these coils to the printed circuit board 17 can be performed stably by means of the separation element 100 and insulating element 200, which are formed on the coil separator 11 and specifically the appearance of a short circuit

  and an electric shock can be avoided.

  Furthermore, since the fluctuation and rotation of the ferrite core 14 in a coupling direction, which can be produced when the ferrite core 14 is coupled to the outer surface of the coil separator 11, is prevented by the parts protruding elastic left and right 400 and 500 formed on the coil separator 11, we can obtain

  an improvement in the dispersion of the image.

  It follows that, since a difference between the left and right magnetic chamos due to the effect of the relative dispersion between the horizontal deflection coil 12 and the vertical deflection coil 13 and / or due to the quantity relative current and a convergence fault and a geometric distortion (L / R) due to this difference can be prevented, the reliability of the deflection block 10 and the tube

cathodic 1 can be increased.

  Preferred typical embodiments of the invention have been described in the foregoing and although specific terms have been used, these are used in a generic and descriptive sense and have no

no limiting character.

Claims (7)

  1. deflection block characterized in that it comprises: a coil separator (11) comprising a back plate and a neck portion, which are arranged in the coil separator and a printed circuit board, which is arranged one side of the coil separator; at least one horizontal deflection coil (12) arranged on a circumferential surface of the coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board, at least one vertical deflection coil (13) arranged on an external surface circumferential of the coil separator to produce a vertical magnetic field; a ferrite core (14) placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils, and having at least a pair of grooves (14a, 14b) having a predetermined width , which are formed on the upper and lower central surfaces of the coils; means (400, 500) for preventing fluctuation, which are formed on the coil separator (11) so that these means have a predetermined elasticity so as to resiliently support the interior surfaces of the pair of grooves in the ferrite core so as to prevent the latter from fluctuating when coupled to the coil separator. 2. deflection block according to claim 1, characterized in that the means (400, 500) serving to prevent fluctuation comprising at least two pairs of elastic protrusions, which are formed so that these two couples extend respectively from an upper inner surface and a lower inner surface of the coil separator and correspond respectively to the pair of grooves (14a, 14b) formed in the ferrite core (14), the two elastic projecting parts of each pair s extending parallel to each other, and the two pairs of elastic projecting parts being inserted elastically respectively in the pair of grooves of the ferrite core in order to compensate for a range of tolerances in width of 0.1 mm - 1.0 mm that presents   each groove (14a, 14b) of the ferrite core.   3. Diversion block, characterized in that it comprises: a coil separator (11) comprising a back plate and a neck portion, which are arranged in the coil separator and a printed circuit board, which is arranged one side of this coil separator; at least one horizontal deflection coil (12) disposed on a circumferential surface of the coil separator so as to produce a horizontal magnetic field and connected to the printed circuit board; at least one vertical deflection coil (13) disposed on a circumferential outer surface of the coil separator to produce a vertical magnetic field; a ferrite core (14) placed on the outer circumferential surface of the coil separator to strengthen the horizontal and vertical magnetic fields of the horizontal and vertical deflection coils, and having at least a pair of grooves (14a, 14b) having a predetermined width , which are formed on the upper and lower central surfaces of the coils; means for preventing fluctuation, which are formed on the coil separator so that these means have a predetermined elasticity so as to resiliently support the internal surfaces of the pair of grooves in the ferrite core so as to prevent the latter from fluctuates when coupled to the coil separator; insulating means (100) formed on a lower surface of the coil separator to prevent the occurrence of a short circuit due to contact between one end and the other end of the horizontal deflection coil connected to the printed circuit board ; means (200) for maintaining the distance between coils, which are formed on an outer surface on one side of the coil holder to ensure a safe distance between the horizontal and vertical deflection coils; and means (400, 500) for preventing fluctuation, which are formed on the coil separator so that these means have a predetermined elasticity so as to resiliently support the interior surfaces of the pair of grooves (14a, 14b) of the ferrite core so as to prevent it from fluctuating if it is coupled to the coil separator.   4. deflection block according to claim 3, characterized in that the insulating means (100) are disposed between boundary surfaces of halves of the   coil separator, which are joined together.   5. deflection block according to claim 3, characterized in that the insulating means (100) comprise a separating element which is formed on a boundary surface of one half of the coil separator so that it extends in the direction from the other boundary surface of the other half of the coil separator to make a separation above and below one end and the other end of the coil horizontal deviation.   6. deflection block according to claim 3, characterized in that the means (200) for maintaining the distance between coils comprises an insulating element which is formed on a surface located on one side of the plate of the coil separator so it extends, while maintaining a predetermined distance from an outer surface of the back plate, so as to isolate the coils of   horizontal and vertical deviation.   7. deflection block according to claim 3, characterized in that the means (400, 500) serving to prevent fluctuation comprise at least two pairs of elastic protrusions, which are formed so that these two couples extend respectively from an upper inner surface and a lower inner surface of the coil separator and correspond respectively to the pair of grooves (14a, 14b) formed in the ferrite core, the two elastic projecting parts of each pair extending in parallel between them, the two pairs of elastic projecting parts being inserted elastically respectively in the pair of grooves of the ferrite core in order to compensate for a range of tolerances in width of 0.1 mm - 1.0 mm than present each groove in the ferrite core.